Dephosphorizing flux and method for preparing same

ABSTRACT

Provided is a dephosphorizing flux configured to adjust a phosphorous component contained in molten steel, the dephosphorizing flux includes a main material including BaCO3 and a supplementary material, wherein the supplementary material includes a first material containing either of NaHCO3 or Na2CO3 and a second material containing CaF2. Thus, in accordance with a dephosphorizing flux and a method for preparing the same of the present disclosure, the plugging of a lower blowing nozzle that blows a carrier gas during dephosphorization may be prevented while improving a dephosphorization ratio. In addition, since environment polluting substances are not used as in conventional arts, environment pollution risk may be reduced, and the cost burden due to the facility for pollution prevention and harmful substance management may be alleviated.

TECHNICAL FIELD

The present disclosure herein relates to a dephosphorizing flux and a method for preparing the same, and more particularly, to a dephosphorizing flux which is capable of improving the dephosphorization efficiency for ferro-manganese and a method for preparing the same.

BACKGROUND ART

Ferro-manganese used as a ferro alloy for steel is being used to adjust a manganese component in general carbon steel, and used by adding ferro-manganese according to the content of manganese (Mn). Here, when increasing the adding ratio of the ferro-manganese, the influence of carbon (C) and phosphorous (P), which are impurities included in the ferro-manganese, increases.

Recently, a product such as a stainless product which contains Mn up to 25 wt % is being developed and produced. As various product groups containing very high Mn content have been developed and produced, the influence of impurity element, contained in the Mn alloy added into molten steel in order to increase the Mn content, to the quality characteristics of steel products has increased.

The representative Mn-alloy element for increasing the Mn content of steel products are Mn metals containing a very high Mn content of at least 99%, and FeMn products containing 15-30 wt % of Fe.

In case of the Mn metals, due to the characteristics of production processes, high purity is maintained with very low contents of impurity elements, so that the influence to the quality characteristic of steel products is low.

However, in case of FeMn, since being produced to generally contain 6-7 wt % of carbon (C) content, 0.08-0.15 wt % of phosphorous (P) content, and less than 0.1 wt % of nitrogen (N) content, the influence of these elements to steel products is high.

The content of carbon (C) contained in FeMn is lowered to the range of 0.5-7 wt % through a dephosphorization process for reducing carbon (C) by blowing oxygen in a dephosphorization refining furnace. Of course, the carbon (C) content may be controlled to be further lowered, if necessary.

In addition, in case of nitrogen (N), the content thereof may be controlled by a method of minimizing nitrogen mixing in a process of producing FeMn, and thus, there is no serious problem.

Meanwhile, in case of phosphorous (P), since being a representative substance that makes brittleness of steel products to be very high, a dephosphorization process for removing phosphorous (P) is very important in steel making process.

The dephosphorization technology for lowering the phosphorous (P) content in FeMn includes a method of using FeMn slag. This method is a production method using slag generated together with high-carbon FeMn that is produced in an electric furnace for producing FeMn. When producing high-carbon FeMn, since phosphorous (P) is mostly distributed toward high-carbon FeMn due to high affinity of phosphorous (P) to Mn, there is a characteristic in that phosphorous is contained in a very small content in the electric furnace slag. Using this, in the method, FeMn is produced by reducing Mn oxides contained in the slag produced in the electric furnace, and the method has a merit in that FeMn with a very low content of carbon (C) may be produced with a very low content of phosphorous (P). However, in this process, SiMn or Al that contains silicon (Si), which is a reducing agent for reducing slag, should be produced or procured, a large scale furnace body should be operated in which the slag produced in the electric furnace are to be warmed and temperature controlled, and a production process such as a process for inducing reaction of the slag and the reducing agent is complicated and require a very long time, and thus, there is a very adverse effect in the aspects of productivity and cost management.

In order to overcome such limitations, a dephosphorization technique is being developed for directly removing phosphorous (P) from a high-carbon molten steel produced in an electric furnace. Representative technology is a method for dephosphorizing high-carbon FeMn through KR agitation and dephosphorizing flux powder blowing methods using a BaCO₃-based flux. In addition, there is a method of controlling the contents of BaCO₃ and BaO in order to improve the dephosphorizing flux used for dephosphorization.

The technique for adjusting the ratio of BaCO₃—BaO has a problem in that a process becomes complicated because a process stage should be undergone in which calcinations reaction of BaCO₃ is induced and BaO should be generated in order to prepare the dephosphorizing flux. In order to use BaO itself, BaO should be produced or procured, but there is a problem in that the production of BaO is difficult in itself, and it is also not easy to store BAO due to a strong hydration reaction. For such reasons, there is no company that industrially produces BaO in large quantities. Therefore, it is also impossible for a FeMn production company to procure and use BaO from another company.

In addition, various research and development have been carried out in which at least one among NaF or Al₂O₃ is added to BaCo₃ as an additive flux.

However, NaF has both functions for a flux and for improving the dephosphorization efficiency, but is designated as a harmful chemical substance. Thus, in order to use NaF, various safety devices and environmental pollution prevention facilities are being required. In addition, since NaF is expensive due to production characteristics, there is a problem of causing a burden of an increase in production cost.

In addition, the addition of Al₂O₃ and the like has a problem of degrading the dephosphorization efficiency.

RELATED PATENT DOCUMENT

(Patent document 1) KR0889859B 1

(Patent document 2) KR1036317B 1

(Patent document 3) KR1036321B 1

DISCLOSURE OF THE INVENTION Technical Problem

The present disclosure herein provides a dephosphorizing flux capable of improving a dephosphorization efficiency for ferro-manganese and a method for preparing the same.

The present disclosure herein also provides a dephosphorizing flux capable of lowering the melting point of slag and securing fluidity and a method for preparing the same.

The present disclosure herein also provides a dephosphorizing flux capable of preventing the occurrence of plugging of a lower blowing nozzle that is provided under a converter, in which dephosphorization is performed, and that blows a gas, and a method for preparing the same. The present disclosure herein also provides a dephosphorizing flux that has a few environment polluting element and is capable of reducing production costs and a method for preparing the same.

Technical Solution

In accordance with an exemplary embodiment, a dephosphorizing flux configured to adjust a phosphorous component contained in molten steel, the dephosphorizing flux including a main material including BaCO₃ and a supplementary material, wherein the supplementary material includes a first material containing either of NaHCO₃ or Na₂CO₃ and a second material containing CaF₂.

The first material may include NaHCO₃ such that the content ratio (CaF₂ wt %/NaHCO₃ wt %) of the second material to the first material is greater than 0 and not greater than 2.3.

The first material may include NaHCO₃ such that the content ratio (CaF₂ wt %/NaHCO₃ wt %) of the second material to the first material is greater than 0 and not greater than 1.4.

The first material may include NaHCO₃ such that the content ratio (CaF₂ wt %/NaHCO₃ wt %) of the second material to the first material is 0.5 to 1 inclusive.

The first material may include Na₂CO₃ such that the content ratio (CaF₂ wt %/Na₂CO₃ wt %) of the second material to the first material is greater than 0 and not greater than 4.

The first material may include Na₂CO₃ such that the content ratio (CaF₂ wt %/Na₂CO₃ wt %) of the second material to the first material is 0.7 to 2 inclusive.

The supplementary material may be greater than 0 wt % and not greater than 30 wt % with respect to the total of the dephosphorizing flux.

The supplementary material may be greater than 0 wt % and not greater than 20 wt % with respect to the total of the dephosphorizing flux.

The second material may be at least 2 wt % with respect to the total of the supplementary material.

In accordance with another exemplary embodiment, a method for preparing a dephosphorizing flux configured to adjust a phosphorous component contained in molten steel, the method including: preparing BaCO₃ which is a main material; preparing a supplementary material comprising a first material comprising either of NaHCO₃ or Na₂CO₃ and a second material comprising CaF₂; and mixing the main material and the supplementary material.

In the preparing of the supplementary material, when the first material includes NaHCO₃, the content ratio (CaF₂ wt %/NaHCO₃ wt %) of the second material to the first material may be configured to be greater than 0 and not greater than 2.3.

In the preparing of the supplementary material, when the first material includes NaHCO₃, the content ratio (CaF₂ wt %/NaHCO₃ wt %) of the second material to the first material may be configured to be greater than 0 and not greater than 1.4.

In the preparing of the supplementary material, when the first material includes NaHCO₃, the content ratio (CaF₂ wt %/NaHCO₃ wt %) of the second material to the first material may be configured to be 0.5 to 1 inclusive.

When the first material includes Na₂CO₃, the content ratio (CaF₂ wt %/Na₂CO₃ wt %) of the second material to the first material may be configured to be greater than 0 and not greater than 4.

When the first material includes Na₂CO₃, the content ratio (CaF₂ wt %/Na₂CO₃ wt %) of the second material to the first material may be configured to be 0.7 to 2 inclusive.

In the mixing of the main material and the supplementary material, the supplementary material may be added to be at most 30 wt % with respect to the total of the dephosphorizing flux.

In the mixing of the main material and the supplementary material, the supplementary material may be added to be at most 20 wt % with respect to the total of the dephosphorizing flux.

In the preparing of the supplementary material, the second material may be added to be at least 2 wt % with respect to the total of the supplementary material.

Advantageous Effects

In accordance with a dephosphorizing flux and a method for preparing the same of the present disclosure, the plugging of a lower blowing nozzle that blows a carrier gas during dephosphorization may be prevented while improving a dephosphorization ratio. In addition, since environment polluting substances are not used as in conventional arts, environment pollution risk may be reduced, and the cost burden due to the facility for pollution prevention and harmful substance management may be alleviated. In addition, there is a cost reduction effect by using NaHCO₃ or Na₂CO₃ and CaF₂ which are relatively cheap.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a flowchart showing a method for preparing a dephosphorizing flux in accordance with an exemplary embodiment.

MODE FOR CARRYING OUT THE INVENTION

Hereinafter, exemplary embodiments will be described in detail with reference to the accompanying drawings. The present disclosure may, however, be embodied in different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the present disclosure to those skilled in the art.

The present disclosure herein provides a dephosphorizing flux used for lowering the content of phosphorous (P) in a ferro-manganese (FeMn) molten steel and a method for producing the same. More specifically, the present disclosure herein provides a dephosphorizing flux which is capable of lowering the melting point of a dephosphorizing flux and slag and improving the dephosphorization efficiency of the ferro-manganese while securing fluidity, has a few environment-polluting elements, and is capable of reducing production costs, and a method for producing the same. As a more specific example, the present disclosure provides a dephosphorizing flux with which dephosphorization is performed with regard to a high-carbon ferro-manganese (FeMn) molten steel having a carbon content of 5-7 wt %, and a method for producing the same.

In addition, the present disclosure herein also provides a dephosphorizing flux which has a dephosphorization ratio due to the dephosphorizing flux is at least 30% and is capable of causing no-plugging of a lower blowing nozzle or preventing the occurrence of plugging of the lower blowing nozzle, and a method for producing the same.

The dephosphorizing flux in accordance with an exemplary embodiment includes at least any one among BaCo₃, NaHCO₃ or Na₂CO₃, which is a highly alkaline material, and CaF₂.

Meanwhile, when the dephosphorizing flux including BaCO₃, which is a highly alkaline material is added into a ferro-manganese molten steel, phosphorous (P) in the ferro-manganese and oxygen react to form a phosphate (P₂O₅), and the phosphate (P₂O₅) is collected by the highly alkaline material and transits into a stable phase. Here, when a highly alkaline oxide is used for the dephosphorizing flux, since the oxide should be present in a liquid phase sate in order to promote a reaction with the phosphate (P₂O₅), a flux is used for lowering the melting point of slag. In addition, it is necessary to use an additive for improving the dephosphorization ratio.

The dephosphorizing flux in accordance with an exemplary embodiment is configured to contain, with respect to the total wt % (100 wt %) of the dephosphorizing flux, at least 70 wt % of a main material and at most 30 wt % of supplementary materials. More favorably, at least 80 wt % of main material and at most 20 wt % of supplementary materials are configured to be contained. Here, the main material may be BaCO₃, and the supplementary materials include at least any one of NaHCO₃ or Na₂CO₃, and CaF₂.

FIG. 1 is a flowchart showing a method for preparing a dephosphorizing flux in accordance with an exemplary embodiment.

Hereinafter referring to FIG. 1, a method for preparing a dephosphorizing flux in accordance with an exemplary embodiment will be described.

Referring to FIG. 1, a method for preparing a dephosphorizing flux in accordance with an exemplary embodiment includes: preparing BaCO₃, which is a main material (S110); preparing supplementary materials (S120); and mixing the main material and the supplementary materials (S200).

The preparing of the supplementary materials (120) includes preparing a first material and a second material (S121 and S122). Here, the first material includes either of NaHCO₃ or Na₂CO₃, and the second material includes CaF₂. NaHCO₃ or Na₂CO₃, functions as a flux for lowering the melting points of the dephosphorizing flux and slag. In addition, CaF₂ functions as an additive for improving the dephosphorization efficiency.

In the mixing of the main material and the supplementary material (S200), the supplementary materials are added so as to be at most 30 wt %, more favorably, at most 20 wt % with respect to the total of the dephosphorizing flux. For example, when the supplementary materials exceed 30 wt %, there is a problem in that the highly alkaline effect due to the use of BaCO₃ is reduced, and the dephosphorization ratio decreases.

The supplementary material is a mixture of the first material and the second material, and NaHCO₃ or Na₂CO₃ are used as the first material and CaF₂ is used as the second material. That is, the supplementary material in accordance with an exemplary embodiment may be configured to include, for example, NaHCO₃ and CaF₂ or to include Na₂CO₃ and CaF₂.

Thus, the dephosphorizing flux in accordance with an exemplary embodiment may be configured to include, for example, NaHCO₃ and CaF₂ or to include Na₂CO₃ and CaF₂.

When adding a powder-state dephosphorizing flux including NaHCO₃ is added into molten steel, a reaction such as the following reaction formula 1 from a low temperature of 60° C. and a large quantity of H₂O and CO₂ are generated simultaneously with blowing. Due to this gas, there is an effect of improving agitating capability of the molten steel, and thus, an additional effect of increasing dephosphorization efficiency may be exhibited. In addition, finally generated Na₂CO₃ is a material having a low melting point of 851° C., and functions as a flux that lowers the melting point of generated dephosphorization slag.

2NaHCO₃-->Na₂CO₃+H₂O+CO₂  Reaction formula 1)

Even when directly using Na₂CO₃ as the first material, the same effect may be generated. That is, the supplementary material may include Na₂CO₃ as the first material, and CaF₂ as the second material. When directly using Na₂CO₃, an effect of increasing the ratio of Na element itself by two times than NaHCO₃ is generated, and an effect is exhibited in which Na₂CO₃ is mixed into the dephosphorization slag by a higher content than NaHCO₃. Thus, an effect of further increasing the function as a flux is exhibited and thus, a dephosphorization effect which is equal to or similar to that of NaHCO₃ is exhibited.

When using the dephosphorizing flux in accordance with the exemplary embodiments, the dephosphorization ratio may be improved by at least 30%. In addition, since the melting points of the dephosphorizing flux and the slag may be lowered and a high fluidity may thereby be maintained, a reaction efficiency with molten steel is high, and since being provided under a converter, the plugging of lower blowing nozzle that blows a carrier gas may be prevented.

In addition, in mixing the main material and the supplementary material including the first material and the second material, the dephosphorization ratio may further be improved by appropriately adjusting the weight ratio of the second material to the first material.

For example, when using NaHCO₃ as the first material, it is effective that the weight ratio (that is, CaF₂ wt %/NaHCO₃ wt %) of the second material (CaF₂) to the first material (NaHCO₃) is adjusted to be greater than 0 and not greater than 2.3. Favorably, the weight ratio (that is, CaF₂ wt %/NaHCO₃ wt %) of the second material (CaF₂) to the first material (NaHCO₃) is adjusted to be greater than approximately 0 and not greater than 1.4, or more favorably, to be 0.5 to 1 inclusive. The weight ratio (that is, CaF₂ wt %/NaHCO₃ wt %) of the second material (CaF₂) to the first material (NaHCO₃) may be adjusted by adjusting the adding amount of the first material, or adjusting the adding amount of the second material.

In addition, in order to improve the dephosphorization efficiency, it is effective to add the second material (CaF₂) to be at least 2 wt % with respect to the total of the supplementary material. That is, there is a tendency that a higher dephosphorization ratio is exhibited when the weight ratio (that is, CaF₂ wt %/NaHCO₃ wt %) of the second material (CaF₂) to the first material (NaHCO₃) is greater than 0 and not greater than 2.3, than that when the second material (CaF₂) is at least 2 wt %, and thus, it is more effective that the second material (CaF₂) is added to be at least 2 wt % with respect to the total of the supplementary material.

Meanwhile, when the second material (CaF₂) is less than 2 wt %, there is a method of increasing the content of the first material (NaHCO₃) in order to adjust the weight ratio (that is, CaF₂ wt %/NaHCO₃ wt %) of the second material (CaF₂) to the first material (NaHCO₃) to be at most 2.3. However, in this method, the dephosphorization ratio is relatively low than that when the second material (CaF₂) is at least 2 wt % and the weight ratio (that is, CaF₂ wt %/NaHCO₃ wt %) of the second material (CaF₂) is adjusted to be at most 2.3. Accordingly, while adjusting the second material (CaF₂) having a larger direct influence to be at least 2 wt %, the weight ratio (that is, CaF₂ wt %/NaHCO₃ wt %) of the second material (CaF₂) to the first material (NaHCO₃) to be at most 2.3, favorably greater than 0 and not greater than 1.4, and more favorably, 0.5 to 1 inclusive.

In another example, when using Na₂CO₃ as the first material, the weight ratio (that is, CaF₂ wt %/Na₂CO₃ wt %) of the second material (CaF₂) to the first material (Na₂CO₃) is favorably adjusted to greater than 0 and not greater than 4, and more favorably adjusted to be 0.7 to 2 inclusive. The weight ratio (that is, CaF₂ wt %/Na₂CO₃ wt %) of the second material (CaF₂) to the first material (Na₂CO₃) may be adjusted by adjusting the adding amount of the first material, or adjusting the adding amount of the second material.

Also in this case, it is effective to add the second material (CaF₂) to be at least 2 wt % with respect to the total of the supplementary material. That is, there is a tendency that a higher dephosphorization ratio is exhibited when the weight ratio (that is, CaF₂ wt %/Na₂CO₃ wt %) of the second material (CaF₂) to the first material (NaHCO₃) is at most 4 than that when the second material (CaF₂) is less than 2 wt %, and thus, it is effective that the second material (CaF₂) is added to be at least 2 wt % with respect to the total of the supplementary material.

Meanwhile, when the second material (CaF₂) is less than 2 wt %, there is a method of increasing the content of the first material (Na₂CO₃) in order to adjust the weight ratio (that is, CaF₂ wt %/Na₂CO₃ wt %) of the second material (CaF₂) to the first material (Na₂CO₃) to be at most 4. However, in this method, the dephosphorization ratio is relatively low than that when the second material (CaF₂) is at least 2 wt % and the weight ratio (that is, CaF₂ wt %/Na₂CO₃ wt %) of the second material (CaF₂) is adjusted to be at most 4. Accordingly, while adjusting the second material (CaF₂) having a larger direct influence to be at least 2 wt %, the weight ratio (that is, CaF₂ wt %/Na₂CO₃ wt %) of the second material (CaF₂) to the first material (Na₂CO₃) to be greater than 0 and not greater than 4, and more favorably, 0.7 to 2 inclusive.

Hereinafter, this will be described through specific and various examples and comparative examples of exemplary embodiments.

Table 1 shows the composition of the dephosphorizing fluxes in accordance with first to sixth comparative examples, and Table 3 shows the dephosphorization ratio when using the dephosphorizing fluxes in accordance with the first to sixth comparative examples and shows whether a lower blowing nozzle provided under a converter is plugged.

Table 2 shows the composition of the dephosphorizing fluxes in accordance with first to ninth examples, and Table 4 shows the dephosphorization ratio when using the dephosphorizing fluxes in accordance with the first to ninth examples and shows whether a lower blowing nozzle provided under a converter is plugged.

The first comparative example is a dephosphorizing flux (BaCO₃100 wt %) which includes only BaCO₃, does not include NaHCO₃ or Na₂CO₃, and does not include CaF₂. In addition, the second comparative example is a dephosphorizing flux which includes BaCO₃ and 10 wt % of NaHCO₃, and does not include CaF₂. In addition, the third and fourth comparative examples are dephosphorizing fluxes which include BaCO₃ and Na₂CO₃, the third comparative example contains 10 wt % of Na₂CO₃, and the fourth example contains 20 wt % of Na₂CO₃. In addition, the fifth and sixth comparative examples are dephosphorizing fluxes which include BaCO₃ and CaF₂, and do not include NaHCO₃ or Na₂CO₃. Here, the content of CaF₂ are different in the fifth and sixth comparative examples

In addition, the dephosphorizing fluxes in accordance with the first to ninth comparative examples each include BaCO₃ as the main material, NaHCO₃ or Na₂CO₃ as the first material for the supplementary material, and CaF₂ as the second material. Here, the dephosphorizing fluxes in accordance with the first to fifth comparative examples each include BaCO₃, NaHCO₃, and CaF₂, and each have different composition contents of respective components. In addition, the dephosphorizing fluxes in accordance with the sixth to ninth comparative examples each include BaCO₃, Na₂CO₃, and CaF₂, and each have different composition contents of respective components.

In addition, in the composition of the first to sixth comparative examples and the first to seventh comparative examples, although the BaCO₃ content is not described, the BaCO₃ content is the remaining content excluding the supplementary material with respect to total dephosphorizing flux of 100 wt %.

TABLE 1 Second material (CaF₂)/ Second material (CaF₂) First material content + first material Dephosphorizing (NaHCO₃ or N₂CO₃) (NaHCO₃ or N₂CO₃) flux composition ratio content (wt %) First BaCO₃ —  0 wt % comparative example Second BaCO₃ + — 10 wt % comparative NaHCO₃ (10 wt %) (NaHCO₃ 10 wt %) example Third BaCO₃ + — 10 wt % comparative Na₂ CO₃ (10 wt %) (Na₂ CO₃ 10 wt %) example Fourth BaCO₃ + — 20 wt % comparative Na₂ CO₃ (20 wt %) (Na₂ CO₃ 20 wt %) example Fifth BaCO₃ + —  5 wt % comparative CaF₂ (5 wt %) (CaF₂ 5 wt %) example Sixth BaCO₃ + — 10 wt % comparative CaF₂ (10 wt %) (CaF₂ 10 wt %) example

TABLE 2 Second material (CaF₂)/ Second material (CaF₂) First material content + first material Dephosphorizing (NaHCO₃ or N₂CO₃) (NaHCO₃ or N₂CO₃) flux composition ratio content (wt %) First BaCO₃ + 1.4 12 wt % comparative NaHCO₃ (5 wt %) + (NaHCO₃ 5 wt % ++ example CaF₂ (7 wt %) CaF₂ 7 wt %) Second BaCO₃ + 1 14 wt % comparative NaHCO₃ (7 wt %) + (NaHCO₃ 7 wt % + example CaF₂ (7 wt %) CaF₂ 7 wt %) Third BaCO₃ + 0.58 19 wt % comparative NaHCO₃ (12 wt %) + NaHCO₃ 12 wt % ++ example CaF₂ (7 wt %) CaF₂ 7 wt %) Fourth BaCO₃ + 2 15 wt % comparative NaHCO₃ (5 wt %) + (NaHCO₃ 5 wt % + example CaF₂ (10 wt %) CaF₂ 10 wt %) Fifth BaCO₃ + 2.3 10 wt % comparative NaHCO₃ (3 wt %) + NaHCO₃ 3 wt % ++ example CaF₂ (7 wt %) CaF₂ 7 wt %) Sixth BaCO₃ + 0.71 12 wt % comparative Na₂ CO₃ (7 wt %) + Na₂ CO₃ 7 wt % + example CaF₂ (5 wt %) CaF₂ 5 wt %) Seventh BaCO₃ + 2.3 10 wt % comparative Na₂ CO₃ (3 wt %) + Na₂ CO₃ 3 wt % + example CaF₂ (7 wt %) CaF₂ 7 wt % Eighth BaCO₃ + 4 15 wt % comparative Na₂ CO₃ (3 wt %) + Na₂ CO₃ 3 wt % + example CaF₂ (12 wt %) CaF₂ 12 wt %) Ninth BaCO₃ + 2 15 wt % comparative Na₂ CO₃ (5 wt %) + Na₂ CO₃ 5 wt % + example CaF₂ (10 wt %) CaF₂ 10 wt %)

TABLE 3 Dephosphorization Dephosphorization Dephosphorization Lower blowing initial stage completion ratio nozzle [P] (wt %) [P] (wt %) [P] (wt %) plugging First 0.106 0.065 39 Plugging comparative occurs example Second 0.112 0.088 21.8 Plugging does comparative not occur example Third 0.104 0.085 18.1 Plugging does comparative not occur example Fourth 0.118 0.091 22.6 Plugging does comparative not occur example Fifth 0.101 0.061 39.2 Plugging comparative occurs example Sixth 0.107 0.058 45.4 Plugging comparative occurs example

TABLE 4 Dephosphorization Dephosphorization Dephosphorization Lower blowing initial stage completion ratio nozzle [P] (wt %) [P] (wt %) [P] (wt %) plugging First 0.109 0.047 49 Plugging does comparative not occur example Second 0.099 0.040 60 Plugging does comparative not occur example Third 0.118 0.049 58.5 Plugging does comparative not occur example Fourth 0.121 0.065 46.2 Plugging does comparative not occur example Fifth 0.132 0.077 41.7 Plugging does comparative not occur example Sixth 0.105 0.04 61.9 Plugging does comparative not occur example Seventh 0.105 0.071 32.4 Plugging does comparative not occur example Eighth 0.123 0.079 35.4 Plugging does comparative not occur example Ninth 0.095 0.054 42.8 Plugging does comparative not occur example

For the experiment, dephosphorization was performed with respect to high-carbon ferro-manganese molten steel containing 5-7 wt % of carbon. In addition, the dephosphorization method was performed such that a lance was immersed in the ferro-manganese molten steel, and then while blowing a carrier gas through a lower blowing nozzle provided under a converter, a dephosphorizing flux was blown into the molten steel. In order to compare under the same conditions, the same unit of the flux of 140 kg/ton was blown, and the final temperature when completing the blowing of the dephosphorizing flux and completing a dephosphorization process were managed to be the same, that is, to be at most 1,310° C.

The dephosphorizing fluxes in accordance with the first to sixth examples and ninth examples have higher dephosphorization ratio than the first comparative example. This is resulted in the example, by an effect of lowering the melting point due to NaHCo3 or Na₂CO₃, an effect of securing fluidity and improving agitating efficiency, and an effect of improving dephosphorization ratio due to CaF₂. Meanwhile, in case of the first comparative example, since the dephosphorizing flux includes only BaCO₃, which is highly alkaline substance and contains a large quantity of BaCO₃, the melting points of the dephosphorizing flux and slag are raised, and thus, the fluidity is lowered. Therefore, the dephosphorization ratio is lower than those in the first to sixth examples and ninth examples.

In addition, when comparing the second comparative example and the first to fifth examples which include NaHCO₃ aside from BaCO₃, the dephosphorization ratios in the first to fifth examples are 1.9 times higher than that in the second comparative example. More specifically, the dephosphorization ratio in the fifth example is 1.9 times higher than that in the first comparative example, and the dephosphorization ratios in the first to fourth examples are 2 times higher, and among these, those in the second and third examples are at least 2.5 times higher.

Meanwhile, the dephosphorization ratio in the second comparative example is higher than that in the third comparative example including 10 wt % of Na₂CO₃, and is similar to that in the fourth comparative example including 20 wt % of Na₂CO₃, but is lower than those of the dephosphorizing fluxes in accordance with the first to ninth examples. This is because the second comparative example does not include CaF₂ that directly affects the dephosphorization ratio.

In addition, when comparing the third to fourth comparative examples and the sixth to ninth examples which include Na₂CO₃ aside from BaCO₃, the dephosphorization ratio in the sixth to ninth examples are approximately 1.4 times higher than those in the third and fourth comparative examples. This is because the third and fourth comparative examples do not include CaF₂, but the sixth to ninth examples include CaF₂ aside from Na₂CO₃. In addition, the dephosphorizing fluxes (the third and fourth comparative examples) in which only Na₂CO₃ is added as the supplementary material functions as a flux in the initial dephosphorization stage, lowers the melting point of the dephosphorizing flux and maintains a molten state, but as the dephosphorization operation is performed, a phenomenon occurs in which the function as the flux may not be performed while Na₂CO₃ is volatized together with the generation of Mn oxides, and thus, the dephosphorization ratio decreases due to solidification of the dephosphorization slag.

Meanwhile, when comparing dephosphorization ratios in accordance with the first comparative example, which does not include CaF₂ and NaHCO₃ or Na₂CO₃, and the fifth and sixth comparative examples which do not include NaHCO₃ or Na₂CO₃, are higher than those in accordance with the seventh to eight examples which include Na₂CO₃ and CaF₂. In addition, when comparing the fifth and sixth comparative examples, a tendency is shown in which the higher the CaF₂ content, the higher the dephosphorization ratio.

However, in case of the dephosphorizing flux including only BaCO₃ (the first comparative example), or including only BaCO₃ and CaF₂ (the fifth and sixth comparative examples), the dephosphorization slag is solidified due to CaO generated while the dephosphorization progresses. Thus, the fluidity of the slag that covers a melt surface becomes very low, and this causes the plugging of a lower blowing nozzle which is provided under a converter and blows an inert gas or a carrier gas in order to move or agitate the powder-like dephosphorizing flux. Therefore, a scattering phenomenon of the molten steel remarkably occurs while the dephosphorization progresses, and in a severe case, a phenomenon of flooding outside a ladle also occurs, and thus, there is a problem of substantially degrading operability.

In addition, in case of the first comparative example, and the fifth to sixth comparative examples, the reaction rate with the molten steel is decreased due to the degradation in the fluidity of the dephosphorizing flux, the dephosphorization ratio is lower than those of the first to sixth examples and the ninth example.

Accordingly, the dephosphorizing fluxes in accordance with exemplary embodiments are configured to include BaCO₃, NaHCO₃ and CaF₂ or to include BaCO₃, Na₂CO₃ and CaF₂, so that the lower blowing nozzle plugging phenomenon may be prevented while having a dephosphorization ratio of at least 30%.

In addition, in accordance with exemplary embodiments, the dephosphorization ratio may further increased by adjusting the ratio of the first material to the second material (CaF₂ wt %/NaHCO₃ wt % or CaF₂ wt %/Na₂CO₃ wt %) that constitutes the supplementary material.

That is, when comparing the first to fifth examples, the dephosphorization ratios of the dephosphorizing fluxes in accordance with the first to third examples, in which the ratio of the first material to the second material (CaF₂ wt %/NaHCO₃ wt % or CaF₂ wt %/Na₂CO₃ wt %) is greater than 0 and not greater than 1.4, exceed 1.4, and this is higher than those of the fourth to fifth examples in which dephosphorization ratio is at most 2.3. This is because the supplementary materials similarly include NAHCO₃ and CaF₂ in the first to fifth examples, but in case of the first to third examples the weight ratio of CaF₂ to NaHCO₃ (that is, CaF₂ wt %/NaHCO₃ wt %) is adjusted to be at most 1.4 while adjusting the NaHCO₃ content corresponding to the CaF₂ content. In other words, this is because in case of the first to third examples, the weight ratio of CaF₂ to NaHCO₃ (that is, CaF₂ wt %/NaHCO₃ wt %) is at most 1.4 while the adding ratio of CAF₂ is reduced compared to those in the fourth to fifth examples, a larger melting point lowering effect due to NaHCO₃ is exhibited in the first to third examples than those in the fourth to fifth examples.

In addition, among the first to fifth example, the dephosphorization ratios of the dephosphorizing fluxes in accordance with the second to third examples, in which the ratio of the first material to the second material (CaF₂ wt %/NaHCO₃ wt %) is 0.5 to 1 inclusive, are higher than those in the first, fourth and fifth examples in which the ratio of the first material to the second material exceeds approximately 1. This is because in the case of the second and third examples, while the adding ratio of CaF₂ decreases compared to the first, fourth, and fifth examples, the weight ratio of CAF₂ to NaHCO₃ (that is, CaF₂ wt %/NaHCO₃ wt %) is 0.5 to 1 inclusive, and thus, a larger melting point lowering effect due to NaHCO₃ is exhibited in the second and third examples than those in the first, fourth and fifth examples.

In addition, the third example shows the result in which dephosphorization was performed in the same manner after mixing NaHCO₃ and CaF₂ while the content ratio of NaHCO₃ is increased up to 12 wt % with respect to the CaF₂ content of 7 wt % in the same manner as the second example. As a result, it was confirmed that the third example exhibited the equal or a similar level of dephosphorization ratio to the second example.

In addition, the dephosphorization ratios of the dephosphorizing fluxes in accordance with the first and fourth examples, in which the weight ratio of CAF₂ to NaHCO₃ (that is, CaF₂ wt %/NaHCO₃ wt %) is greater than 1 and not greater than 2, are higher than those of the first to sixth comparative examples, and the plugging of the lower blowing nozzle does not occur.

Comparing the sixth to ninth examples, the dephosphorization ratio of the dephosphorizing fluxes in accordance with the sixth example is higher than those of the dephosphorizing fluxes in accordance with the seventh to ninth examples. This is because in case of the dephosphorizing fluxes in accordance with the sixth example, the weight ratio of CaF₂ to Na₂CO₃ is adjusted to be 0.7 to 2 inclusive, and the degree of increase in the melting point of slag due to an increase in CaO according to a progress in dephosphorization is relatively lower than those in the seventh to ninth examples, and the reaction efficiency is relatively high.

In addition, it may be found that the sixth example, which includes BaCO₃, Na₂CO₃ and CaF₂ and in which the weight ratio of CaF₂ to Na₂CO₃ is 0.7 to 2 inclusive, exhibits a dephosphorization ratio which is equal or similar to those of the second and third examples which includes BaCO₃, NaHCO₃ and CaF₂ and in which the weight ratio of CaF₂ to NaHCO₃ is 0.5 to 1.4 inclusive.

As such, according to the dephosphorizing flux in accordance with an exemplary embodiment, the plugging of the lower blowing nozzle that blows a carrier gas during dephosphorization may be prevented while securing a dephosphorization ratio of at least 30%. In addition, in configuring the supplementary material for the dephosphorizing flux,

The occurrence of nozzle plugging may be prevented or suppressed while securing a dephosphorization ratio of at least 41% by adjusting the weight ratio (that is, CaF₂ wt %/NaHCO₃ wt %) of the second material (CaF₂) to the first material (NaHCO₃) to be greater than 0 and not greater than 2.3. In addition, favorably, the occurrence of nozzle plugging may be prevented or suppressed while securing a dephosphorization ratio of at least 49% by adjusting the weight ratio (that is, CaF₂ wt %/NaHCO₃ wt %) of the second material (CaF₂) to the first material (NaHCO₃) to be greater than 0 and not greater than 1.4. In addition, more favorably, the occurrence of nozzle plugging may be prevented or suppressed while securing a dephosphorization ratio of at least 55% by adjusting the weight ratio (that is, CaF₂ wt %/NaHCO₃ wt %) of the second material (CaF₂) to the first material (NaHCO₃) to be greater than 0.5 and not greater than 1.

In addition, the occurrence of nozzle plugging may be prevented or suppressed while securing a dephosphorization ratio of at least 30% by adjusting the weight ratio (that is, CaF₂ wt %/NaHCO₃ wt %) of the second material (CaF₂) to the first material (NaHCO₃) to be greater than 0 and not greater than 4. More favorably, the occurrence of nozzle plugging may be prevented or suppressed while securing a dephosphorization ratio of at least 40% by adjusting the weight ratio (that is, CaF₂ wt %/NaHCO₃ wt %) of the second material (CaF₂) to the first material (NaHCO₃) to be 0.7 to 2 inclusive.

In addition, since environment polluting substances are not used as in conventional arts, environment pollution risk may be reduced, and the cost burden due to the facility for pollution prevention and harmful substance management may be alleviated. In addition, there is a cost reduction effect by using NaHCO₃ or Na₂CO₃ and CaF₂ which are relatively cheap

INDUSTRIAL APPLICABILITY

According to the dephosphorizing flux and a method for preparing the same in accordance with exemplary embodiments, the plugging of a lower blowing nozzle that blows a carrier gas during dephosphorization may be prevented while improving a dephosphorization ratio. In addition, since environment polluting substances are not used as in conventional arts, environment pollution risk may be reduced, and the cost burden due to the facility for pollution prevention and harmful substance management may be alleviated. 

1. A dephosphorizing flux configured to adjust a phosphorous component contained in molten steel, the dephosphorizing flux comprising a main material comprising BaCO₃ and a supplementary material, wherein the supplementary material comprises a first material comprising either of NaHCO₃ or Na₂CO₃ and a second material comprising CaF₂.
 2. The dephosphorizing flux of claim 1, wherein the first material comprises NaHCO₃ such that a content ratio (CaF₂ wt %/NaHCO₃ wt %) of the second material to the first material is greater than 0 and not greater than 2.3.
 3. The dephosphorizing flux of claim 2, wherein the first material comprises NaHCO₃ such that the content ratio (CaF₂ wt %/NaHCO₃ wt %) of the second material to the first material is greater than 0 and not greater than 1.4.
 4. The dephosphorizing flux of claim 3, wherein the first material comprises NaHCO₃ such that the content ratio (CaF₂ wt %/NaHCO₃ wt %) of the second material to the first material is 0.5 to 1 inclusive.
 5. The dephosphorizing flux of claim 1, wherein the first material comprises Na₂CO₃ such that the content ratio (CaF₂ wt %/Na₂CO₃ wt %) of the second material to the first material is greater than 0 and not greater than
 4. 6. The dephosphorizing flux of claim 4, wherein the first material comprises Na₂CO₃ such that the content ratio (CaF₂ wt %/Na₂CO₃ wt %) of the second material to the first material is 0.7 to 2 inclusive.
 7. The dephosphorizing flux of claim 1, wherein the supplementary material is greater than 0 wt % and not greater than 30 wt % with respect to the total of the dephosphorizing flux.
 8. The dephosphorizing flux of claim 7, wherein the supplementary material is greater than 0 wt % and not greater than 20 wt % with respect to the total of the dephosphorizing flux.
 9. The dephosphorizing flux of claim 1, wherein the second material is at least 2 wt % with respect to the total of the supplementary material.
 10. A method for preparing a dephosphorizing flux configured to adjust a phosphorous component contained in molten steel, the method comprising: preparing BaCO₃ which is a main material; preparing a supplementary material comprising a first material comprising either of NaHCO₃ or Na₂CO₃ and a second material comprising CaF₂; and mixing the main material and the supplementary material.
 11. The method of claim 10, wherein in the preparing of the supplementary material, when the first material comprises NaHCO₃, the content ratio (CaF₂ wt %/NaHCO₃ wt %) of the second material to the first material is configured to be greater than 0 and not greater than 2.3.
 12. The method of claim 11, wherein in the preparing of the supplementary material, when the first material comprises NaHCO₃, the content ratio (CaF₂ wt %/NaHCO₃ wt %) of the second material to the first material is configured to be greater than 0 and not greater than 1.4.
 13. The method of claim 12, wherein in the preparing of the supplementary material, when the first material comprises NaHCO₃, the content ratio (CaF₂ wt %/NaHCO₃ wt %) of the second material to the first material is configured to be 0.5 to 1 inclusive.
 14. The method of claim 10, wherein when the first material comprises Na₂CO₃, the content ratio (CaF₂ wt %/Na₂CO₃ wt %) of the second material to the first material is greater than 0 and not greater than
 4. 15. The method of claim 14, wherein when the first material comprises Na₂CO₃, the content ratio (CaF₂ wt %/Na₂CO₃ wt %) of the second material to the first material is 0.7 to 2 inclusive.
 16. The method of claim 10, wherein in the mixing of the main material and the supplementary material, the supplementary material is added to be at most approximately 30 wt % with respect to the total of the dephosphorizing flux.
 17. The method of claim 16, wherein in the mixing of the main material and the supplementary material, the supplementary material is added to be at most 20 wt % with respect to the total of the dephosphorizing flux.
 18. The method of claim 10, wherein in the preparing the supplementary material, the second material is added to be at least 2 wt % with respect to the total of the supplementary material. 